src/gen/gensurf.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/*
 *  gensurf.c - program to generate functional surfaces
 *
 *      Parametric functions x(s,t), y(s,t) and z(s,t)
 *  specify the surface, which is tesselated into an m by n
 *  array of paired triangles.
 *      The surface normal is defined by the right hand
 *  rule applied to (s,t).
 *
 *      4/3/87
 *
 *      4/16/02 Added conditional vertex output
 */

#include  "standard.h"

char  XNAME[] =         "X`SYS";                /* x function name */
char  YNAME[] =         "Y`SYS";                /* y function name */
char  ZNAME[] =         "Z`SYS";                /* z function name */

char  VNAME[] =         "valid";                /* valid vertex name */

#define  ABS(x)         ((x)>=0 ? (x) : -(x))

#define  ZEROVECT(v)    (DOT(v,v) <= FTINY*FTINY)

#define  pvect(p)       printf(vformat, (p)[0], (p)[1], (p)[2])

char  vformat[] = "%15.9g %15.9g %15.9g\n";
char  tsargs[] = "4 surf_dx surf_dy surf_dz surf.cal\n";
char  texname[] = "Phong";

int  smooth = 0;                /* apply smoothing? */
int  objout = 0;                /* output .OBJ format? */

char  *modname, *surfname;

                                /* recorded data flags */
#define  HASBORDER      01
#define  TRIPLETS       02
                                /* a data structure */
struct {
        int     flags;                  /* data type */
        short   m, n;                   /* number of s and t values */
        FLOAT   *data;                  /* the data itself, s major sort */
} datarec;                      /* our recorded data */

double  l_hermite(), l_bezier(), l_bspline(), l_dataval();
extern double  funvalue(), argument();

typedef struct {
        int  valid;     /* point is valid (vertex number) */
        FVECT  p;       /* vertex position */
        FVECT  n;       /* average normal */
        FLOAT  uv[2];   /* (u,v) position */
} POINT;


main(argc, argv)
int  argc;
char  *argv[];
{
        extern long     eclock;
        POINT  *row0, *row1, *row2, *rp;
        int  i, j, m, n;
        char  stmp[256];

        varset("PI", ':', PI);
        funset("hermite", 5, ':', l_hermite);
        funset("bezier", 5, ':', l_bezier);
        funset("bspline", 5, ':', l_bspline);

        if (argc < 8)
                goto userror;

        for (i = 8; i < argc; i++)
                if (!strcmp(argv[i], "-e"))
                        scompile(argv[++i], NULL, 0);
                else if (!strcmp(argv[i], "-f"))
                        fcompile(argv[++i]);
                else if (!strcmp(argv[i], "-s"))
                        smooth++;
                else if (!strcmp(argv[i], "-o"))
                        objout++;
                else
                        goto userror;

        modname = argv[1];
        surfname = argv[2];
        m = atoi(argv[6]);
        n = atoi(argv[7]);
        if (m <= 0 || n <= 0)
                goto userror;
        if (!strcmp(argv[5], "-") || access(argv[5], 4) == 0) { /* file? */
                funset(ZNAME, 2, ':', l_dataval);
                if (!strcmp(argv[5],argv[3]) && !strcmp(argv[5],argv[4])) {
                        loaddata(argv[5], m, n, 3);
                        funset(XNAME, 2, ':', l_dataval);
                        funset(YNAME, 2, ':', l_dataval);
                } else {
                        loaddata(argv[5], m, n, 1);
                        sprintf(stmp, "%s(s,t)=%s;", XNAME, argv[3]);
                        scompile(stmp, NULL, 0);
                        sprintf(stmp, "%s(s,t)=%s;", YNAME, argv[4]);
                        scompile(stmp, NULL, 0);
                }
        } else {
                sprintf(stmp, "%s(s,t)=%s;", XNAME, argv[3]);
                scompile(stmp, NULL, 0);
                sprintf(stmp, "%s(s,t)=%s;", YNAME, argv[4]);
                scompile(stmp, NULL, 0);
                sprintf(stmp, "%s(s,t)=%s;", ZNAME, argv[5]);
                scompile(stmp, NULL, 0);
        }
        row0 = (POINT *)malloc((n+3)*sizeof(POINT));
        row1 = (POINT *)malloc((n+3)*sizeof(POINT));
        row2 = (POINT *)malloc((n+3)*sizeof(POINT));
        if (row0 == NULL || row1 == NULL || row2 == NULL) {
                fprintf(stderr, "%s: out of memory\n", argv[0]);
                quit(1);
        }
        row0++; row1++; row2++;
                                                /* print header */
        printhead(argc, argv);
        eclock = 0;
                                                /* initialize */
        comprow(-1.0/m, row0, n);
        comprow(0.0, row1, n);
        comprow(1.0/m, row2, n);
        compnorms(row0, row1, row2, n);
        if (objout) {
                printf("\nusemtl %s\n\n", modname);
                putobjrow(row1, n);
        }
                                                /* for each row */
        for (i = 0; i < m; i++) {
                                                /* compute next row */
                rp = row0;
                row0 = row1;
                row1 = row2;
                row2 = rp;
                comprow((double)(i+2)/m, row2, n);
                compnorms(row0, row1, row2, n);
                if (objout)
                        putobjrow(row1, n);

                for (j = 0; j < n; j++) {
                        int  orient = (j & 1);
                                                        /* put polygons */
                        if (!(row0[j].valid && row1[j+1].valid))
                                orient = 1;
                        else if (!(row1[j].valid && row0[j+1].valid))
                                orient = 0;
                        if (orient)
                                putsquare(&row0[j], &row1[j],
                                                &row0[j+1], &row1[j+1]);
                        else
                                putsquare(&row1[j], &row1[j+1],
                                                &row0[j], &row0[j+1]);
                }
        }

        quit(0);

userror:
        fprintf(stderr, "Usage: %s material name ", argv[0]);
        fprintf(stderr, "x(s,t) y(s,t) z(s,t) m n [-s][-e expr][-f file]\n");
        quit(1);
}


loaddata(file, m, n, pointsize)         /* load point data from file */
char  *file;
int  m, n;
int  pointsize;
{
        FILE  *fp;
        char  word[64];
        register int  size;
        register FLOAT  *dp;

        datarec.flags = HASBORDER;              /* assume border values */
        datarec.m = m+1;
        datarec.n = n+1;
        size = datarec.m*datarec.n*pointsize;
        if (pointsize == 3)
                datarec.flags |= TRIPLETS;
        dp = (FLOAT *)malloc(size*sizeof(FLOAT));
        if ((datarec.data = dp) == NULL) {
                fputs("Out of memory\n", stderr);
                exit(1);
        }
        if (!strcmp(file, "-")) {
                file = "<stdin>";
                fp = stdin;
        } else if ((fp = fopen(file, "r")) == NULL) {
                fputs(file, stderr);
                fputs(": cannot open\n", stderr);
                exit(1);
        }
        while (size > 0 && fgetword(word, sizeof(word), fp) != NULL) {
                if (!isflt(word)) {
                        fprintf(stderr, "%s: garbled data value: %s\n",
                                        file, word);
                        exit(1);
                }
                *dp++ = atof(word);
                size--;
        }
        if (size == (m+n+1)*pointsize) {        /* no border after all */
                dp = (FLOAT *)realloc((char *)datarec.data,
                                m*n*pointsize*sizeof(FLOAT));
                if (dp != NULL)
                        datarec.data = dp;
                datarec.flags &= ~HASBORDER;
                datarec.m = m;
                datarec.n = n;
                size = 0;
        }
        if (datarec.m < 2 || datarec.n < 2 || size != 0 ||
                        fgetword(word, sizeof(word), fp) != NULL) {
                fputs(file, stderr);
                fputs(": bad number of data points\n", stderr);
                exit(1);
        }
        fclose(fp);
}


double
l_dataval(nam)                          /* return recorded data value */
char  *nam;
{
        double  u, v;
        register int  i, j;
        register FLOAT  *dp;
        double  d00, d01, d10, d11;
                                                /* compute coordinates */
        u = argument(1); v = argument(2);
        if (datarec.flags & HASBORDER) {
                i = u *= datarec.m-1;
                j = v *= datarec.n-1;
        } else {
                i = u = u*datarec.m - .5;
                j = v = v*datarec.n - .5;
        }
        if (i < 0) i = 0;
        else if (i > datarec.m-2) i = datarec.m-2;
        if (j < 0) j = 0;
        else if (j > datarec.n-2) j = datarec.n-2;
                                                /* compute value */
        if (datarec.flags & TRIPLETS) {
                dp = datarec.data + 3*(j*datarec.m + i);
                if (nam == ZNAME)
                        dp += 2;
                else if (nam == YNAME)
                        dp++;
                d00 = dp[0]; d01 = dp[3];
                dp += 3*datarec.m;
                d10 = dp[0]; d11 = dp[3];
        } else {
                dp = datarec.data + j*datarec.m + i;
                d00 = dp[0]; d01 = dp[1];
                dp += datarec.m;
                d10 = dp[0]; d11 = dp[1];
        }
                                                /* bilinear interpolation */
        return((j+1-v)*((i+1-u)*d00+(u-i)*d01)+(v-j)*((i+1-u)*d10+(u-i)*d11));
}


putobjrow(rp, n)                        /* output vertex row to .OBJ */
register POINT  *rp;
int  n;
{
        static int      nverts = 0;

        for ( ; n-- >= 0; rp++) {
                if (!rp->valid)
                        continue;
                fputs("v ", stdout);
                pvect(rp->p);
                if (smooth && !ZEROVECT(rp->n))
                        printf("\tvn %.9g %.9g %.9g\n",
                                        rp->n[0], rp->n[1], rp->n[2]);
                printf("\tvt %.9g %.9g\n", rp->uv[0], rp->uv[1]);
                rp->valid = ++nverts;
        }
}


putsquare(p0, p1, p2, p3)               /* put out a square */
POINT  *p0, *p1, *p2, *p3;
{
        static int  nout = 0;
        FVECT  norm[4];
        int  axis;
        FVECT  v1, v2, vc1, vc2;
        int  ok1, ok2;
                                        /* compute exact normals */
        ok1 = (p0->valid && p1->valid && p2->valid);
        if (ok1) {
                VSUB(v1, p1->p, p0->p);
                VSUB(v2, p2->p, p0->p);
                fcross(vc1, v1, v2);
                ok1 = (normalize(vc1) != 0.0);
        }
        ok2 = (p1->valid && p2->valid && p3->valid);
        if (ok2) {
                VSUB(v1, p2->p, p3->p);
                VSUB(v2, p1->p, p3->p);
                fcross(vc2, v1, v2);
                ok2 = (normalize(vc2) != 0.0);
        }
        if (!(ok1 | ok2))
                return;
        if (objout) {                   /* output .OBJ faces */
                int     p0n=0, p1n=0, p2n=0, p3n=0;
                if (smooth) {
                        if (!ZEROVECT(p0->n))
                                p0n = p0->valid;
                        if (!ZEROVECT(p1->n))
                                p1n = p1->valid;
                        if (!ZEROVECT(p2->n))
                                p2n = p2->valid;
                        if (!ZEROVECT(p3->n))
                                p3n = p3->valid;
                }
                if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
                        printf("f %d/%d/%d %d/%d/%d %d/%d/%d %d/%d/%d\n",
                                        p0->valid, p0->valid, p0n,
                                        p1->valid, p1->valid, p1n,
                                        p3->valid, p3->valid, p3n,
                                        p2->valid, p2->valid, p2n);
                        return;
                }
                if (ok1)
                        printf("f %d/%d/%d %d/%d/%d %d/%d/%d\n",
                                        p0->valid, p0->valid, p0n,
                                        p1->valid, p1->valid, p1n,
                                        p2->valid, p2->valid, p2n);
                if (ok2)
                        printf("f %d/%d/%d %d/%d/%d %d/%d/%d\n",
                                        p2->valid, p2->valid, p2n,
                                        p1->valid, p1->valid, p1n,
                                        p3->valid, p3->valid, p3n);
                return;
        }
                                        /* compute normal interpolation */
        axis = norminterp(norm, p0, p1, p2, p3);

                                        /* put out quadrilateral? */
        if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
                printf("\n%s ", modname);
                if (axis != -1) {
                        printf("texfunc %s\n", texname);
                        printf(tsargs);
                        printf("0\n13\t%d\n", axis);
                        pvect(norm[0]);
                        pvect(norm[1]);
                        pvect(norm[2]);
                        fvsum(v1, norm[3], vc1, -0.5);
                        fvsum(v1, v1, vc2, -0.5);
                        pvect(v1);
                        printf("\n%s ", texname);
                }
                printf("polygon %s.%d\n", surfname, ++nout);
                printf("0\n0\n12\n");
                pvect(p0->p);
                pvect(p1->p);
                pvect(p3->p);
                pvect(p2->p);
                return;
        }
                                        /* put out triangles? */
        if (ok1) {
                printf("\n%s ", modname);
                if (axis != -1) {
                        printf("texfunc %s\n", texname);
                        printf(tsargs);
                        printf("0\n13\t%d\n", axis);
                        pvect(norm[0]);
                        pvect(norm[1]);
                        pvect(norm[2]);
                        fvsum(v1, norm[3], vc1, -1.0);
                        pvect(v1);
                        printf("\n%s ", texname);
                }
                printf("polygon %s.%d\n", surfname, ++nout);
                printf("0\n0\n9\n");
                pvect(p0->p);
                pvect(p1->p);
                pvect(p2->p);
        }
        if (ok2) {
                printf("\n%s ", modname);
                if (axis != -1) {
                        printf("texfunc %s\n", texname);
                        printf(tsargs);
                        printf("0\n13\t%d\n", axis);
                        pvect(norm[0]);
                        pvect(norm[1]);
                        pvect(norm[2]);
                        fvsum(v2, norm[3], vc2, -1.0);
                        pvect(v2);
                        printf("\n%s ", texname);
                }
                printf("polygon %s.%d\n", surfname, ++nout);
                printf("0\n0\n9\n");
                pvect(p2->p);
                pvect(p1->p);
                pvect(p3->p);
        }
}


comprow(s, row, siz)                    /* compute row of values */
double  s;
register POINT  *row;
int  siz;
{
        double  st[2];
        int  end;
        int  checkvalid;
        register int  i;
        
        if (smooth) {
                i = -1;                 /* compute one past each end */
                end = siz+1;
        } else {
                if (s < -FTINY || s > 1.0+FTINY)
                        return;
                i = 0;
                end = siz;
        }
        st[0] = s;
        checkvalid = (fundefined(VNAME) == 2);
        while (i <= end) {
                st[1] = (double)i/siz;
                if (checkvalid && funvalue(VNAME, 2, st) <= 0.0) {
                        row[i].valid = 0;
                        row[i].p[0] = row[i].p[1] = row[i].p[2] = 0.0;
                        row[i].uv[0] = row[i].uv[1] = 0.0;
                } else {
                        row[i].valid = 1;
                        row[i].p[0] = funvalue(XNAME, 2, st);
                        row[i].p[1] = funvalue(YNAME, 2, st);
                        row[i].p[2] = funvalue(ZNAME, 2, st);
                        row[i].uv[0] = st[0];
                        row[i].uv[1] = st[1];
                }
                i++;
        }
}


compnorms(r0, r1, r2, siz)              /* compute row of averaged normals */
register POINT  *r0, *r1, *r2;
int  siz;
{
        FVECT  v1, v2;

        if (!smooth)                    /* not needed if no smoothing */
                return;
                                        /* compute row 1 normals */
        while (siz-- >= 0) {
                if (!r1[0].valid)
                        continue;
                if (!r0[0].valid) {
                        if (!r2[0].valid) {
                                r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
                                continue;
                        }
                        fvsum(v1, r2[0].p, r1[0].p, -1.0);
                } else if (!r2[0].valid)
                        fvsum(v1, r1[0].p, r0[0].p, -1.0);
                else
                        fvsum(v1, r2[0].p, r0[0].p, -1.0);
                if (!r1[-1].valid) {
                        if (!r1[1].valid) {
                                r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
                                continue;
                        }
                        fvsum(v2, r1[1].p, r1[0].p, -1.0);
                } else if (!r1[1].valid)
                        fvsum(v2, r1[0].p, r1[-1].p, -1.0);
                else
                        fvsum(v2, r1[1].p, r1[-1].p, -1.0);
                fcross(r1[0].n, v1, v2);
                normalize(r1[0].n);
                r0++; r1++; r2++;
        }
}


int
norminterp(resmat, p0, p1, p2, p3)      /* compute normal interpolation */
register FVECT  resmat[4];
POINT  *p0, *p1, *p2, *p3;
{
#define u  ((ax+1)%3)
#define v  ((ax+2)%3)

        register int  ax;
        MAT4  eqnmat;
        FVECT  v1;
        register int  i, j;

        if (!smooth)                    /* no interpolation if no smoothing */
                return(-1);
                                        /* find dominant axis */
        VCOPY(v1, p0->n);
        fvsum(v1, v1, p1->n, 1.0);
        fvsum(v1, v1, p2->n, 1.0);
        fvsum(v1, v1, p3->n, 1.0);
        ax = ABS(v1[0]) > ABS(v1[1]) ? 0 : 1;
        ax = ABS(v1[ax]) > ABS(v1[2]) ? ax : 2;
                                        /* assign equation matrix */
        eqnmat[0][0] = p0->p[u]*p0->p[v];
        eqnmat[0][1] = p0->p[u];
        eqnmat[0][2] = p0->p[v];
        eqnmat[0][3] = 1.0;
        eqnmat[1][0] = p1->p[u]*p1->p[v];
        eqnmat[1][1] = p1->p[u];
        eqnmat[1][2] = p1->p[v];
        eqnmat[1][3] = 1.0;
        eqnmat[2][0] = p2->p[u]*p2->p[v];
        eqnmat[2][1] = p2->p[u];
        eqnmat[2][2] = p2->p[v];
        eqnmat[2][3] = 1.0;
        eqnmat[3][0] = p3->p[u]*p3->p[v];
        eqnmat[3][1] = p3->p[u];
        eqnmat[3][2] = p3->p[v];
        eqnmat[3][3] = 1.0;
                                        /* invert matrix (solve system) */
        if (!invmat4(eqnmat, eqnmat))
                return(-1);                     /* no solution */
                                        /* compute result matrix */
        for (j = 0; j < 4; j++)
                for (i = 0; i < 3; i++)
                        resmat[j][i] =  eqnmat[j][0]*p0->n[i] +
                                        eqnmat[j][1]*p1->n[i] +
                                        eqnmat[j][2]*p2->n[i] +
                                        eqnmat[j][3]*p3->n[i];
        return(ax);

#undef u
#undef v
}


void
eputs(msg)
char  *msg;
{
        fputs(msg, stderr);
}


void
wputs(msg)
char  *msg;
{
        eputs(msg);
}


void
quit(code)
int  code;
{
        exit(code);
}


printhead(ac, av)               /* print command header */
register int  ac;
register char  **av;
{
        putchar('#');
        while (ac--) {
                putchar(' ');
                fputs(*av++, stdout);
        }
        putchar('\n');
}


double
l_hermite()                     
{
        double  t;
        
        t = argument(5);
        return( argument(1)*((2.0*t-3.0)*t*t+1.0) +
                argument(2)*(-2.0*t+3.0)*t*t +
                argument(3)*((t-2.0)*t+1.0)*t +
                argument(4)*(t-1.0)*t*t );
}


double
l_bezier()
{
        double  t;

        t = argument(5);
        return( argument(1) * (1.+t*(-3.+t*(3.-t))) +
                argument(2) * 3.*t*(1.+t*(-2.+t)) +
                argument(3) * 3.*t*t*(1.-t) +
                argument(4) * t*t*t );
}


double
l_bspline()
{
        double  t;

        t = argument(5);
        return( argument(1) * (1./6.+t*(-1./2.+t*(1./2.-1./6.*t))) +
                argument(2) * (2./3.+t*t*(-1.+1./2.*t)) +
                argument(3) * (1./6.+t*(1./2.+t*(1./2.-1./2.*t))) +
                argument(4) * (1./6.*t*t*t) );
}
Revision:	2.9
Committed:	Wed Mar 12 04:59:04 2003 UTC (22 years, 7 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad3R5
Changes since 2.8:	+26 -20 lines
Log Message:	Numerous bug fixes in new mesh code
#	User	Rev	Content
1	greg	1.1	#ifndef lint
2	greg	2.7	static const char RCSid[] = "$Id$";
3	greg	1.1	#endif
4	greg	1.2	/*
5	greg	1.1	* gensurf.c - program to generate functional surfaces
6			*
7			* Parametric functions x(s,t), y(s,t) and z(s,t)
8			* specify the surface, which is tesselated into an m by n
9			* array of paired triangles.
10			* The surface normal is defined by the right hand
11			* rule applied to (s,t).
12			*
13			* 4/3/87
14	greg	2.6	*
15			* 4/16/02 Added conditional vertex output
16	greg	1.1	*/
17
18	greg	1.5	#include "standard.h"
19	greg	1.1
20	greg	2.6	char XNAME[] = "X`SYS"; /* x function name */
21			char YNAME[] = "Y`SYS"; /* y function name */
22			char ZNAME[] = "Z`SYS"; /* z function name */
23
24			char VNAME[] = "valid"; /* valid vertex name */
25	greg	1.1
26	greg	1.4	#define ABS(x) ((x)>=0 ? (x) : -(x))
27
28	greg	2.9	#define ZEROVECT(v) (DOT(v,v) <= FTINY*FTINY)
29
30	greg	1.3	#define pvect(p) printf(vformat, (p)[0], (p)[1], (p)[2])
31	greg	1.1
32			char vformat[] = "%15.9g %15.9g %15.9g\n";
33	greg	1.3	char tsargs[] = "4 surf_dx surf_dy surf_dz surf.cal\n";
34			char texname[] = "Phong";
35	greg	1.1
36	greg	1.3	int smooth = 0; /* apply smoothing? */
37	greg	2.7	int objout = 0; /* output .OBJ format? */
38	greg	1.1
39	greg	1.3	char modname, surfname;
40	greg	1.1
41	greg	2.2	/* recorded data flags */
42			#define HASBORDER 01
43			#define TRIPLETS 02
44			/* a data structure */
45			struct {
46			int flags; /* data type */
47			short m, n; /* number of s and t values */
48			FLOAT data; / the data itself, s major sort */
49			} datarec; /* our recorded data */
50	greg	1.3
51	greg	2.2	double l_hermite(), l_bezier(), l_bspline(), l_dataval();
52			extern double funvalue(), argument();
53
54	greg	1.3	typedef struct {
55	greg	2.7	int valid; /* point is valid (vertex number) */
56	greg	1.3	FVECT p; /* vertex position */
57			FVECT n; /* average normal */
58	greg	2.7	FLOAT uv[2]; /* (u,v) position */
59	greg	1.3	} POINT;
60
61
62	greg	1.1	main(argc, argv)
63			int argc;
64			char *argv[];
65			{
66	greg	1.9	extern long eclock;
67	greg	1.3	POINT row0, row1, row2, rp;
68	greg	1.1	int i, j, m, n;
69			char stmp[256];
70
71	greg	1.13	varset("PI", ':', PI);
72	greg	1.14	funset("hermite", 5, ':', l_hermite);
73			funset("bezier", 5, ':', l_bezier);
74			funset("bspline", 5, ':', l_bspline);
75	greg	1.1
76			if (argc < 8)
77			goto userror;
78
79			for (i = 8; i < argc; i++)
80			if (!strcmp(argv[i], "-e"))
81	greg	1.10	scompile(argv[++i], NULL, 0);
82	greg	1.1	else if (!strcmp(argv[i], "-f"))
83			fcompile(argv[++i]);
84	greg	1.3	else if (!strcmp(argv[i], "-s"))
85			smooth++;
86	greg	2.7	else if (!strcmp(argv[i], "-o"))
87			objout++;
88	greg	1.1	else
89			goto userror;
90
91	greg	1.3	modname = argv[1];
92			surfname = argv[2];
93	greg	1.1	m = atoi(argv[6]);
94			n = atoi(argv[7]);
95			if (m <= 0 \|\| n <= 0)
96			goto userror;
97	greg	2.2	if (!strcmp(argv[5], "-") \|\| access(argv[5], 4) == 0) { /* file? */
98			funset(ZNAME, 2, ':', l_dataval);
99			if (!strcmp(argv[5],argv[3]) && !strcmp(argv[5],argv[4])) {
100			loaddata(argv[5], m, n, 3);
101			funset(XNAME, 2, ':', l_dataval);
102			funset(YNAME, 2, ':', l_dataval);
103			} else {
104			loaddata(argv[5], m, n, 1);
105			sprintf(stmp, "%s(s,t)=%s;", XNAME, argv[3]);
106			scompile(stmp, NULL, 0);
107			sprintf(stmp, "%s(s,t)=%s;", YNAME, argv[4]);
108			scompile(stmp, NULL, 0);
109			}
110			} else {
111			sprintf(stmp, "%s(s,t)=%s;", XNAME, argv[3]);
112			scompile(stmp, NULL, 0);
113			sprintf(stmp, "%s(s,t)=%s;", YNAME, argv[4]);
114			scompile(stmp, NULL, 0);
115			sprintf(stmp, "%s(s,t)=%s;", ZNAME, argv[5]);
116			scompile(stmp, NULL, 0);
117			}
118	greg	1.4	row0 = (POINT )malloc((n+3)sizeof(POINT));
119			row1 = (POINT )malloc((n+3)sizeof(POINT));
120			row2 = (POINT )malloc((n+3)sizeof(POINT));
121	greg	1.3	if (row0 == NULL \|\| row1 == NULL \|\| row2 == NULL) {
122	greg	1.1	fprintf(stderr, "%s: out of memory\n", argv[0]);
123			quit(1);
124			}
125	greg	1.4	row0++; row1++; row2++;
126	greg	1.3	/* print header */
127	greg	1.1	printhead(argc, argv);
128	greg	1.9	eclock = 0;
129	greg	1.4	/* initialize */
130			comprow(-1.0/m, row0, n);
131	greg	1.3	comprow(0.0, row1, n);
132			comprow(1.0/m, row2, n);
133	greg	1.4	compnorms(row0, row1, row2, n);
134	greg	2.8	if (objout) {
135			printf("\nusemtl %s\n\n", modname);
136	greg	2.7	putobjrow(row1, n);
137	greg	2.8	}
138	greg	1.3	/* for each row */
139	greg	1.1	for (i = 0; i < m; i++) {
140			/* compute next row */
141	greg	1.3	rp = row0;
142	greg	1.1	row0 = row1;
143	greg	1.3	row1 = row2;
144			row2 = rp;
145	greg	1.4	comprow((double)(i+2)/m, row2, n);
146			compnorms(row0, row1, row2, n);
147	greg	2.7	if (objout)
148			putobjrow(row1, n);
149	greg	1.1
150			for (j = 0; j < n; j++) {
151	greg	2.6	int orient = (j & 1);
152	greg	1.3	/* put polygons */
153	greg	2.7	if (!(row0[j].valid && row1[j+1].valid))
154	greg	2.6	orient = 1;
155	greg	2.7	else if (!(row1[j].valid && row0[j+1].valid))
156	greg	2.6	orient = 0;
157			if (orient)
158	greg	1.3	putsquare(&row0[j], &row1[j],
159			&row0[j+1], &row1[j+1]);
160			else
161			putsquare(&row1[j], &row1[j+1],
162			&row0[j], &row0[j+1]);
163	greg	1.1	}
164			}
165
166			quit(0);
167
168			userror:
169			fprintf(stderr, "Usage: %s material name ", argv[0]);
170	greg	1.3	fprintf(stderr, "x(s,t) y(s,t) z(s,t) m n [-s][-e expr][-f file]\n");
171	greg	1.1	quit(1);
172	greg	2.2	}
173
174
175			loaddata(file, m, n, pointsize) /* load point data from file */
176			char *file;
177			int m, n;
178			int pointsize;
179			{
180			FILE *fp;
181			char word[64];
182			register int size;
183			register FLOAT *dp;
184
185			datarec.flags = HASBORDER; /* assume border values */
186	greg	2.3	datarec.m = m+1;
187			datarec.n = n+1;
188			size = datarec.mdatarec.npointsize;
189	greg	2.2	if (pointsize == 3)
190			datarec.flags \|= TRIPLETS;
191			dp = (FLOAT )malloc(sizesizeof(FLOAT));
192			if ((datarec.data = dp) == NULL) {
193			fputs("Out of memory\n", stderr);
194			exit(1);
195			}
196			if (!strcmp(file, "-")) {
197			file = "<stdin>";
198			fp = stdin;
199			} else if ((fp = fopen(file, "r")) == NULL) {
200			fputs(file, stderr);
201			fputs(": cannot open\n", stderr);
202			exit(1);
203			}
204			while (size > 0 && fgetword(word, sizeof(word), fp) != NULL) {
205			if (!isflt(word)) {
206			fprintf(stderr, "%s: garbled data value: %s\n",
207			file, word);
208			exit(1);
209			}
210			*dp++ = atof(word);
211			size--;
212			}
213			if (size == (m+n+1)pointsize) { / no border after all */
214			dp = (FLOAT )realloc((char )datarec.data,
215			mnpointsize*sizeof(FLOAT));
216			if (dp != NULL)
217			datarec.data = dp;
218			datarec.flags &= ~HASBORDER;
219	greg	2.3	datarec.m = m;
220			datarec.n = n;
221	greg	2.2	size = 0;
222			}
223	greg	2.3	if (datarec.m < 2 \|\| datarec.n < 2 \|\| size != 0 \|\|
224			fgetword(word, sizeof(word), fp) != NULL) {
225	greg	2.2	fputs(file, stderr);
226			fputs(": bad number of data points\n", stderr);
227			exit(1);
228			}
229			fclose(fp);
230			}
231
232
233			double
234			l_dataval(nam) /* return recorded data value */
235			char *nam;
236			{
237			double u, v;
238			register int i, j;
239			register FLOAT *dp;
240			double d00, d01, d10, d11;
241			/* compute coordinates */
242			u = argument(1); v = argument(2);
243			if (datarec.flags & HASBORDER) {
244	greg	2.3	i = u *= datarec.m-1;
245			j = v *= datarec.n-1;
246	greg	2.2	} else {
247	greg	2.3	i = u = u*datarec.m - .5;
248			j = v = v*datarec.n - .5;
249	greg	2.2	}
250			if (i < 0) i = 0;
251			else if (i > datarec.m-2) i = datarec.m-2;
252			if (j < 0) j = 0;
253			else if (j > datarec.n-2) j = datarec.n-2;
254			/* compute value */
255			if (datarec.flags & TRIPLETS) {
256	greg	2.3	dp = datarec.data + 3(jdatarec.m + i);
257			if (nam == ZNAME)
258			dp += 2;
259			else if (nam == YNAME)
260	greg	2.2	dp++;
261			d00 = dp[0]; d01 = dp[3];
262	greg	2.3	dp += 3*datarec.m;
263	greg	2.2	d10 = dp[0]; d11 = dp[3];
264			} else {
265	greg	2.3	dp = datarec.data + j*datarec.m + i;
266	greg	2.2	d00 = dp[0]; d01 = dp[1];
267	greg	2.3	dp += datarec.m;
268	greg	2.2	d10 = dp[0]; d11 = dp[1];
269			}
270			/* bilinear interpolation */
271			return((j+1-v)((i+1-u)d00+(u-i)d01)+(v-j)((i+1-u)d10+(u-i)d11));
272	greg	1.1	}
273
274
275	greg	2.7	putobjrow(rp, n) /* output vertex row to .OBJ */
276			register POINT *rp;
277			int n;
278			{
279			static int nverts = 0;
280
281			for ( ; n-- >= 0; rp++) {
282			if (!rp->valid)
283			continue;
284			fputs("v ", stdout);
285	greg	2.9	pvect(rp->p);
286			if (smooth && !ZEROVECT(rp->n))
287	greg	2.7	printf("\tvn %.9g %.9g %.9g\n",
288			rp->n[0], rp->n[1], rp->n[2]);
289			printf("\tvt %.9g %.9g\n", rp->uv[0], rp->uv[1]);
290			rp->valid = ++nverts;
291			}
292			}
293
294
295	greg	1.3	putsquare(p0, p1, p2, p3) /* put out a square */
296			POINT p0, p1, p2, p3;
297			{
298			static int nout = 0;
299			FVECT norm[4];
300			int axis;
301			FVECT v1, v2, vc1, vc2;
302			int ok1, ok2;
303			/* compute exact normals */
304	greg	2.7	ok1 = (p0->valid && p1->valid && p2->valid);
305	greg	2.6	if (ok1) {
306	greg	2.9	VSUB(v1, p1->p, p0->p);
307			VSUB(v2, p2->p, p0->p);
308	greg	2.6	fcross(vc1, v1, v2);
309			ok1 = (normalize(vc1) != 0.0);
310			}
311	greg	2.7	ok2 = (p1->valid && p2->valid && p3->valid);
312	greg	2.6	if (ok2) {
313	greg	2.9	VSUB(v1, p2->p, p3->p);
314			VSUB(v2, p1->p, p3->p);
315	greg	2.6	fcross(vc2, v1, v2);
316			ok2 = (normalize(vc2) != 0.0);
317			}
318	greg	1.3	if (!(ok1 \| ok2))
319			return;
320	greg	2.7	if (objout) { /* output .OBJ faces */
321			int p0n=0, p1n=0, p2n=0, p3n=0;
322			if (smooth) {
323	greg	2.9	if (!ZEROVECT(p0->n))
324			p0n = p0->valid;
325			if (!ZEROVECT(p1->n))
326			p1n = p1->valid;
327			if (!ZEROVECT(p2->n))
328			p2n = p2->valid;
329			if (!ZEROVECT(p3->n))
330			p3n = p3->valid;
331	greg	2.7	}
332			if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
333			printf("f %d/%d/%d %d/%d/%d %d/%d/%d %d/%d/%d\n",
334	greg	2.9	p0->valid, p0->valid, p0n,
335			p1->valid, p1->valid, p1n,
336			p3->valid, p3->valid, p3n,
337			p2->valid, p2->valid, p2n);
338	greg	2.7	return;
339			}
340			if (ok1)
341			printf("f %d/%d/%d %d/%d/%d %d/%d/%d\n",
342	greg	2.9	p0->valid, p0->valid, p0n,
343			p1->valid, p1->valid, p1n,
344			p2->valid, p2->valid, p2n);
345	greg	2.7	if (ok2)
346			printf("f %d/%d/%d %d/%d/%d %d/%d/%d\n",
347	greg	2.9	p2->valid, p2->valid, p2n,
348			p1->valid, p1->valid, p1n,
349			p3->valid, p3->valid, p3n);
350	greg	2.7	return;
351			}
352	greg	1.3	/* compute normal interpolation */
353			axis = norminterp(norm, p0, p1, p2, p3);
354
355			/* put out quadrilateral? */
356			if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
357			printf("\n%s ", modname);
358			if (axis != -1) {
359			printf("texfunc %s\n", texname);
360			printf(tsargs);
361			printf("0\n13\t%d\n", axis);
362			pvect(norm[0]);
363			pvect(norm[1]);
364			pvect(norm[2]);
365			fvsum(v1, norm[3], vc1, -0.5);
366			fvsum(v1, v1, vc2, -0.5);
367			pvect(v1);
368			printf("\n%s ", texname);
369			}
370			printf("polygon %s.%d\n", surfname, ++nout);
371			printf("0\n0\n12\n");
372			pvect(p0->p);
373			pvect(p1->p);
374			pvect(p3->p);
375			pvect(p2->p);
376			return;
377			}
378			/* put out triangles? */
379			if (ok1) {
380			printf("\n%s ", modname);
381			if (axis != -1) {
382			printf("texfunc %s\n", texname);
383			printf(tsargs);
384			printf("0\n13\t%d\n", axis);
385			pvect(norm[0]);
386			pvect(norm[1]);
387			pvect(norm[2]);
388			fvsum(v1, norm[3], vc1, -1.0);
389			pvect(v1);
390			printf("\n%s ", texname);
391			}
392			printf("polygon %s.%d\n", surfname, ++nout);
393			printf("0\n0\n9\n");
394			pvect(p0->p);
395			pvect(p1->p);
396			pvect(p2->p);
397			}
398			if (ok2) {
399			printf("\n%s ", modname);
400			if (axis != -1) {
401			printf("texfunc %s\n", texname);
402			printf(tsargs);
403			printf("0\n13\t%d\n", axis);
404			pvect(norm[0]);
405			pvect(norm[1]);
406			pvect(norm[2]);
407			fvsum(v2, norm[3], vc2, -1.0);
408			pvect(v2);
409			printf("\n%s ", texname);
410			}
411			printf("polygon %s.%d\n", surfname, ++nout);
412			printf("0\n0\n9\n");
413			pvect(p2->p);
414			pvect(p1->p);
415			pvect(p3->p);
416			}
417			}
418
419
420	greg	1.1	comprow(s, row, siz) /* compute row of values */
421			double s;
422	greg	1.3	register POINT *row;
423	greg	1.1	int siz;
424			{
425	greg	1.4	double st[2];
426	greg	1.8	int end;
427	greg	2.6	int checkvalid;
428	greg	1.4	register int i;
429	greg	1.8
430			if (smooth) {
431			i = -1; /* compute one past each end */
432			end = siz+1;
433			} else {
434			if (s < -FTINY \|\| s > 1.0+FTINY)
435			return;
436			i = 0;
437			end = siz;
438			}
439	greg	1.1	st[0] = s;
440	greg	2.6	checkvalid = (fundefined(VNAME) == 2);
441	greg	1.8	while (i <= end) {
442	greg	1.4	st[1] = (double)i/siz;
443	greg	2.6	if (checkvalid && funvalue(VNAME, 2, st) <= 0.0) {
444			row[i].valid = 0;
445			row[i].p[0] = row[i].p[1] = row[i].p[2] = 0.0;
446	greg	2.7	row[i].uv[0] = row[i].uv[1] = 0.0;
447	greg	2.6	} else {
448			row[i].valid = 1;
449			row[i].p[0] = funvalue(XNAME, 2, st);
450			row[i].p[1] = funvalue(YNAME, 2, st);
451			row[i].p[2] = funvalue(ZNAME, 2, st);
452	greg	2.7	row[i].uv[0] = st[0];
453			row[i].uv[1] = st[1];
454	greg	2.6	}
455	greg	1.8	i++;
456	greg	1.1	}
457	greg	1.3	}
458
459
460			compnorms(r0, r1, r2, siz) /* compute row of averaged normals */
461			register POINT r0, r1, *r2;
462			int siz;
463			{
464	greg	1.11	FVECT v1, v2;
465	greg	1.3
466			if (!smooth) /* not needed if no smoothing */
467			return;
468	greg	2.6	/* compute row 1 normals */
469	greg	1.4	while (siz-- >= 0) {
470	greg	2.6	if (!r1[0].valid)
471			continue;
472			if (!r0[0].valid) {
473			if (!r2[0].valid) {
474			r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
475			continue;
476			}
477			fvsum(v1, r2[0].p, r1[0].p, -1.0);
478			} else if (!r2[0].valid)
479			fvsum(v1, r1[0].p, r0[0].p, -1.0);
480			else
481			fvsum(v1, r2[0].p, r0[0].p, -1.0);
482			if (!r1[-1].valid) {
483			if (!r1[1].valid) {
484			r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
485			continue;
486			}
487			fvsum(v2, r1[1].p, r1[0].p, -1.0);
488			} else if (!r1[1].valid)
489			fvsum(v2, r1[0].p, r1[-1].p, -1.0);
490			else
491			fvsum(v2, r1[1].p, r1[-1].p, -1.0);
492	greg	1.3	fcross(r1[0].n, v1, v2);
493			normalize(r1[0].n);
494			r0++; r1++; r2++;
495			}
496			}
497
498
499			int
500			norminterp(resmat, p0, p1, p2, p3) /* compute normal interpolation */
501			register FVECT resmat[4];
502			POINT p0, p1, p2, p3;
503			{
504			#define u ((ax+1)%3)
505			#define v ((ax+2)%3)
506
507			register int ax;
508	greg	1.12	MAT4 eqnmat;
509	greg	1.3	FVECT v1;
510			register int i, j;
511
512			if (!smooth) /* no interpolation if no smoothing */
513			return(-1);
514			/* find dominant axis */
515			VCOPY(v1, p0->n);
516			fvsum(v1, v1, p1->n, 1.0);
517			fvsum(v1, v1, p2->n, 1.0);
518			fvsum(v1, v1, p3->n, 1.0);
519	greg	1.4	ax = ABS(v1[0]) > ABS(v1[1]) ? 0 : 1;
520			ax = ABS(v1[ax]) > ABS(v1[2]) ? ax : 2;
521	greg	1.3	/* assign equation matrix */
522			eqnmat[0][0] = p0->p[u]*p0->p[v];
523			eqnmat[0][1] = p0->p[u];
524			eqnmat[0][2] = p0->p[v];
525			eqnmat[0][3] = 1.0;
526			eqnmat[1][0] = p1->p[u]*p1->p[v];
527			eqnmat[1][1] = p1->p[u];
528			eqnmat[1][2] = p1->p[v];
529			eqnmat[1][3] = 1.0;
530			eqnmat[2][0] = p2->p[u]*p2->p[v];
531			eqnmat[2][1] = p2->p[u];
532			eqnmat[2][2] = p2->p[v];
533			eqnmat[2][3] = 1.0;
534			eqnmat[3][0] = p3->p[u]*p3->p[v];
535			eqnmat[3][1] = p3->p[u];
536			eqnmat[3][2] = p3->p[v];
537			eqnmat[3][3] = 1.0;
538			/* invert matrix (solve system) */
539	greg	2.5	if (!invmat4(eqnmat, eqnmat))
540	greg	1.3	return(-1); /* no solution */
541			/* compute result matrix */
542			for (j = 0; j < 4; j++)
543			for (i = 0; i < 3; i++)
544	greg	1.4	resmat[j][i] = eqnmat[j][0]*p0->n[i] +
545			eqnmat[j][1]*p1->n[i] +
546			eqnmat[j][2]*p2->n[i] +
547			eqnmat[j][3]*p3->n[i];
548	greg	1.3	return(ax);
549
550			#undef u
551			#undef v
552	greg	1.1	}
553
554
555	greg	2.6	void
556	greg	1.1	eputs(msg)
557			char *msg;
558			{
559			fputs(msg, stderr);
560			}
561
562
563	greg	2.6	void
564	greg	1.1	wputs(msg)
565			char *msg;
566			{
567			eputs(msg);
568			}
569
570
571	greg	2.6	void
572	greg	1.1	quit(code)
573	greg	2.4	int code;
574	greg	1.1	{
575			exit(code);
576			}
577
578
579			printhead(ac, av) /* print command header */
580			register int ac;
581			register char **av;
582			{
583			putchar('#');
584			while (ac--) {
585			putchar(' ');
586			fputs(*av++, stdout);
587			}
588			putchar('\n');
589			}
590
591
592			double
593			l_hermite()
594			{
595			double t;
596
597			t = argument(5);
598			return( argument(1)((2.0t-3.0)tt+1.0) +
599			argument(2)(-2.0t+3.0)tt +
600			argument(3)((t-2.0)t+1.0)*t +
601			argument(4)(t-1.0)t*t );
602	greg	1.6	}
603
604
605			double
606			l_bezier()
607			{
608			double t;
609
610			t = argument(5);
611			return( argument(1) * (1.+t(-3.+t(3.-t))) +
612			argument(2) * 3.t(1.+t*(-2.+t)) +
613			argument(3) * 3.tt*(1.-t) +
614			argument(4) * ttt );
615	greg	1.7	}
616
617
618			double
619			l_bspline()
620			{
621			double t;
622
623			t = argument(5);
624			return( argument(1) * (1./6.+t(-1./2.+t(1./2.-1./6.*t))) +
625			argument(2) * (2./3.+tt(-1.+1./2.*t)) +
626			argument(3) * (1./6.+t(1./2.+t(1./2.-1./2.*t))) +
627			argument(4) * (1./6.tt*t) );
628	greg	1.1	}